My watch list
my.chemeurope.com  
Login  

Measuring ethanol’s deadly twin

18-Sep-2019

Van den Broek J et al. Nature Communications 2019

In this image, the sensor is inside the white casing. To its right is the polymer tube in which methanol is separated from ethanol.

ETH researchers have developed an inexpensive, handheld measuring device that can distinguish between methanol and potable alcohol. It offers a simple, quick method of detecting adulterated or contaminated alcoholic beverages and is able to diagnose methanol poisoning in exhaled breath.

Methanol is sometimes referred to as ethanol’s deadly twin. While the latter is the intoxicating ingredient in wine, beer and schnapps, the former is a chemical that becomes highly toxic when metabolised by the human body. Even a relatively small amount of methanol can cause blindness or even prove fatal if left untreated.

Cases of poisoning from the consumption of alcoholic beverages tainted with methanol occur time and again, particularly in developing and emerging countries, because alcoholic fermentation also produces small quantities of methanol. Whenever alcohol is unprofessionally distilled in backyard operations, relevant amounts of methanol may end up in the liquor. Beverages that have been adulterated with windscreen washer fluid or other liquids containing methanol are another potential cause of poisoning.

Beverage analyses and the breath test

Until now, methanol could be distinguished from ethanol only in a chemical analysis laboratory. Even hospitals require relatively large, expensive equipment in order to diagnose methanol poisoning. “These appliances are rarely available in emerging and developing countries, where outbreaks of methanol poisoning are most prevalent,” says Andreas Güntner, a research group leader at the Particle Technology Laboratory of ETH Professor Sotiris Pratsinis and a researcher at the University Hospital Zurich.

He and his colleagues have now developed an affordable handheld device based on a small metal oxide sensor. It is able to detect adulterated alcohol within two minutes by “sniffing out” methanol and ethanol vapours from a beverage. Moreover, the tool can also be used to diagnose methanol poisoning by analysing a patient’s exhaled breath. In an emergency, this helps ensure the appropriate measures are taken without delay.

Separating methanol from ethanol

There’s nothing new about using metal oxide sensors to measure alcoholic vapours. However, this method was unable to distinguish between different alcohols, such as ethanol and methanol. “Even the breathalyser tests used by the police measure only ethanol, although some devices also erroneously identify methanol as ethanol,” explains Jan van den Broek, a doctoral student at ETH and the lead author of the study.

First, the ETH scientists developed a highly sensitive alcohol sensor using nanoparticles of tin oxide doped with palladium. Next, they used a trick to differentiate between methanol and ethanol. Instead of analysing the sample directly with the sensor, the two types of alcohol are first separated in an attached tube filled with a porous polymer, through which the sample air is sucked by a small pump. As its molecules are smaller, methanol passes through the polymer tube more quickly than ethanol.

The measuring device proved to be exceptionally sensitive. In laboratory tests, it detected even trace amounts of methanol contamination selectively in alcoholic beverages, down to the low legal limits. Furthermore, the scientists analysed breath samples from a person who had previously drunk rum. For test purposes, the researchers subsequently added a small quantity of methanol to the breath sample.

Patent pending

The researchers have filed a patent application for the measuring method. They are now working to integrate the technology into a device that can be put to practical use. “This technology is low cost, making it suitable for use in developing countries as well. Moreover, it’s simple to use and can be operated even without laboratory training, for example by authorities or tourists,” Güntner says. It is also ideal for quality control in distilleries.

Methanol is more than just a nuisance in conjunction with alcoholic beverages, it is also an important industrial chemical – and one that might come to play an even more important role: methanol is being considered as a potential future fuel, since vehicles can be powered with methanol fuel cells. So a further application for the new technology could be as an alarm sensor to detect leaks in tanks.

Facts, background information, dossiers
  • beverage analysis
  • Alcoholic beverages
  • breath analysis
More about ETH Zürich
  • News

    Using industrial waste as insulation for buildings

    ETH spinoff FenX transforms industrial waste into a porous foam suitable for building insulation. Unlike other sustainable materials used for the purpose, this type of insulation is non-flammable and inexpensive to produce. No sooner does one of the four young men come up with the idea than ... more

    Deep learning, prefabricated

    Self-driving cars, the automatic detection of cancer cells, online translation: deep learning makes it all possible. The ETH spin-off Mirage Technologies has developed a deep learning platform that aims to help start-ups and companies more quickly develop and optimise their products. The na ... more

    Mini-spectrometer: Smaller than a coin

    ETH researchers have developed a compact infrared spectrometer. It’s small enough to fit on a computer chip but can still open up interesting possibilities – in space and in everyday life. Nowadays, a mobile phone can do almost anything: take photos or video, send messages, determine its pr ... more

  • Videos

    Oxybromination of methane over vanadium phosphate

    ETH Zurich scientists have discovered a new catalyst that allows the easy conversion of natural gas constituents into precursors for the production of fuels or complex chemicals, such as polymers or pharmaceuticals. The new catalyst is extremely stable and results in fewer unwanted by-produ ... more

Your browser is not current. Microsoft Internet Explorer 6.0 does not support some functions on Chemie.DE